KR101451606B1 - optical cable divergence method in Fiber Optic Splice Closure for Aerial Line - Google Patents

Abstract

Disclosed is an optical cable divergence method in a fiber optical connection enclosure for intermediate divergence. The optical cable divergence method according to an embodiment of the present invention comprises the steps of molting an intermediate cover of a conventional optical cable and cutting only a loose tube, to be used in the intermediate divergence among multiple loose tubes, in half; connecting dummy cores for extending a length of an optical core wire which is diverged from the loose tube after removing the intermediate cover of the cut loose tube; protecting the dummy cores which are connected to the optical core wire by using an expanded protection tube and a connection point of the dummy cores; and mounting the conventional optical cable at the enclosure in order to dispose the cut loose tube and the dummy cores in the enclosure.

Description

TECHNICAL FIELD [0001] The present invention relates to an optical cable divergence method in a fiber optic splice closure for an aerial branch,

More particularly, the present invention relates to an optical fiber branching method for an intermediate branch, and more particularly, to an optical fiber branching method for a middle branching optical fiber, To an optical cable branching method in a connection enclosure.

Since the optical cable is provided in a finite length, the optical transmission line between the telephone office and the subscriber building or general optical subscriber requires an optical connection box, and the optical fibers in the optical cable are interconnected in the field through the optical connection box. In order for the optical fiber in the optical cable to be interconnected with the transmission device of the optical subscriber in the optical transmission line on the optical subscriber side, the optical fiber from the optical cable must be distributed to the optical subscriber. For this purpose, the optical fiber is installed on the outer wall of the optical subscriber building, The optical cable connection housing is required.

An optical cable connection enclosure is one of subscriber termination devices that performs a connection and distribution function between an external optical line and a subscriber transmission device. An optical fiber in an inserted optical cable is connected to an optical fiber of a single fiber (or an optical jumper cord) And the remaining optical fibers in the optical cable are optically connected and then re-fetched in the form of an optical cable to be distributed to the long distance optical network transmission apparatus.

On the other hand, when the optical cable is branched to a new optical fiber transmission device at a distance from the above-mentioned optical cable connection housing, there are many problems such as the cost of installation, workability and licensing. Particularly, there is a problem that the optical cable can not branch at the optimum point in the branching operation of the optical cable, unnecessarily the extension optical cable is extended to a specific place, and the stability of the optical fiber (optical fiber cable) There is a problem to be solved.

Published Patent No. 2012-0044858

Embodiments of the present invention are to provide an optical cable branching method in an intermediate branching optical fiber connection case capable of branching only a part of optical core (core) from an existing optical cable without covering a unit (loose tube) inside the enclosure.

Embodiments of the present invention provide an optical cable branching method in an intermediate optical fiber splice housing which is easy to branch and stably protects optical fiber lines and connection points.

Embodiments of the present invention provide an optical cable branching method in an intermediate branchless optical fiber connection enclosure capable of branchless branching.

The objects of the present invention are not limited thereto, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a method of manufacturing an optical fiber cable, the method comprising: breaking an intermediate sheath of an existing optical cable, cutting only a loose tube to be used as an intermediate branch among a plurality of loose tubes; Connecting the dummy cores to extend the lengths of the optical fibers diverging from the loose tube after removing the envelope of the loose tube cut in half; Protecting an attachment point of the dummy cores and the dummy cores connected to the optical fibers with an expanded protection tube; And mounting the optical fiber cable to the housing so that the loose tube and the dummy cores cut in half are positioned on the housing, the optical cable branching method in the intermediate branchless optical fiber connector can be provided.

In addition, in the step of attaching the existing optical cable to the housing, the extender protection tube may be fixed to the fastening plate after passing through a protective tube guide provided at the bottom of the housing.

Preparing a new cable, removing the loose tube of the new cable, and protecting the loose tube of the new cable using the unit protection tube; And mounting the new cable to the housing.

In addition, in the step of mounting the new cable to the housing, the unit protection tube may be fixed to the fastening plate after passing through the protection tube guide so as to intersect or parallel with the expanded protection tube and the X-shaped protrusion.

The expanded protection tube may further include a connection point of the dummy cores and the optical core wires are located in a first tube of the expanded protective tube, the dummy core extending from the first tube and having a diameter smaller than the first tube And may be located in the second tube.

The embodiments of the present invention have a remarkable effect that only a part of optical fiber lines can be branched from an existing optical cable in use without wearing a unit (loose tube) inside the enclosure.

The embodiments of the present invention can prevent the damage of the optical fiber line by safely wrapping and protecting the connection points of the optical fiber line and the dummy cores exposed to the outside during branching operation of the existing optical fiber cable, .

FIG. 1 is a perspective view showing a non-optical fiber connection box for a middle branch according to an embodiment of the present invention.
FIG. 2 is a front view showing an intermediate branching optical fiber connection box according to an embodiment of the present invention. FIG.
FIGS. 3A to 4C are diagrams showing steps of branching a loose tube required in an existing optical cable.
5A and 5B are diagrams for explaining a branching method capable of branching optical fiber lines from each of the loose tubes cut in half.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an optical cable branching method for a middle branching optical fiber connection enclosure according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a perspective view showing a non-optical fiber splice closure for intermediate splitting according to an embodiment of the present invention, and FIG. 2 is a front view showing a splice splice splicing optical fiber splice closure according to an embodiment of the present invention.

The middle branching non-single-fiber optical fiber bundle 10 according to the present invention is designed to break the middle casing of the existing optical fiber cable 20 without covering the optical fiber inside the enclosure 100 and to selectively branch only the necessary unit (loose tube) .

Referring to FIG. 1, the intermediate splice non-single-fiber splice housing 10 according to the present invention includes a housing 100 and a mounting module 900.

The enclosure 100 is fixed to the ground wire GW by the mounting module 900 and an optical cable 20 and a new optical cable 30 are inserted into the enclosure 100 .

The hypothetical module 900 is for fixing the enclosure 100 to the ground wire GW so that the enclosure 100 is installed in the air and may be installed at a plurality of points on the upper end of the enclosure 100. [ For example, the hypothetical module 900 may be installed on both left and right sides of the upper end of the housing 100, respectively.

The housing 100 can be opened or closed for connection of the optical cable in a state where it is fixed to the ground line GW by the provisional member 900.

The housing 100 includes a first housing 100a and a second housing 100b. The first housing 100a and the second housing 100b have a structure in which a front surface is opened, and a lower end thereof is hinged to be opened / closed in a rotating manner. The first housing 100a is fixed to the ground wire GW by the temporary fixing member 900 and the housing 100 is fixed to the ground wire GW 2 can be opened and closed by rotation of the housing 100b.

When the first housing 100a is closed by the rotation of the second housing 100b, the first and second housings 100a and 100b can be locked by the lock module 300. [ And, for connection of the optical cable, the first and second housings 100a and 100b can be unlocked by the lock module 300. The locking module 300 may include a locking lever 320 and a lever locking portion 340.

The first optical fiber cable 20 is provided on the side surface of the first housing 100a with a branching optical fiber inlet 112 through which the optical fiber cable 20 is inserted, And the cable fixing bracket 115, as shown in Fig.

In addition, a one-piece cable gasket 114 is installed for maintaining the airtightness at the time of entering the existing optical cable 20 and for convenience of the intermediate branch construction. Three cable gaskets (114) can be used to accommodate various diameters of optical cables. The type is classified into type 1 that can accommodate optical cable diameter Φ10-13, type2 that can accommodate optical cable diameter Φ13-16, and type3 which can accommodate optical cable diameter Φ16-19. Also, the one-piece cable gasket 114 can be installed not only in the branching optical fiber inlet 112 but also in the optical fiber inlet 116 for connection.

In addition, a side of the first housing 100a is provided with a connecting optical cable inlet 116 through which a new optical cable 30 is inserted. The optical fiber cable inlet 116 for connection is positioned in parallel with the optical fiber cable inlet 112 for branching. A cone-shaped cable gasket 118 is installed in the optical fiber cable inlet 116 for maintaining a perfect airtightness when the optical fiber cable 30 is inserted. The jacket of the new optical fiber cable 30 can be fixed by the jacket holder 113 and the suspension band bracket 117 and the center line of the new optical fiber cable 30 can be fixed by the jacket fixing module 160 which is the center.

A support plate 140 is provided on the housing 100. The support plate 140 is hinged to the first housing 100a. The support plate 140 can be folded forward (180 degrees) or horizontally (90 degrees). A plate-shaped girdle plate is installed on the girder support base 140.

The existing optical cable 20 and the installation optical cable 30 are drawn into the enclosure 100 in the state in which the enclosure 100 is opened and are branched and connected. After completion of the construction, the enclosure 100 is kept closed to protect the branch portion of the optical cable 20 and the connection portion of the optical fiber from the external environment.

The optical cable branching and connection construction method in the intermediate branching non-branching optical fiber bundle 10 having the above-described configuration is as follows.

FIGS. 3A to 4C are diagrams showing steps of branching a loose tube required in an existing optical cable.

As shown in FIG. 3A, the untwisted position is indicated by using a paper tape or a pen on the existing optical cable 20, and then the outer jacket excluding the center tension line and the aramid yarn are removed. For example, the stripping width of the existing optical cable 20 may be approximately 370 mm.

As shown in FIGS. 3B to 3D, the roof tube 22 to be used as an intermediate branch among the plurality of exposed rouge tubes 22 is cut in half while the outer shell is removed (FIG. 3B). The unused loose tube 22 of the split loose tube 22 inserts the protection tube 70 to protect the optical fiber line and the other removes the envelope leaving 60 mm from the exposed end , Fig. 3d).

As shown in FIG. 3E, since the optical core wires 24 exposed in the loose tube 22 from which the shell is removed are short in length and difficult to work, the length of the optical core wire 24 is extended, Extension work is carried out. In the core wire extending operation, the optical core wires 24 to be used as the intermediate branch and the dummy cores 40 provided as accessories are connected by the heat-shrinkable sleeve 50.

As shown in FIG. 3F, the extended protective tube 80 is used to protect the dummy cores 40 connected to the optical core wires 24 and the connection points (heat shrinkable sleeves) of the dummy cores 40. The extended protection tube 80 is provided for securely protecting the connection points of the dummy core and the optical cores exposed to the outside from the loose tube 22 and may be provided in the form of a flexible tube having different diameters. Specifically, the expanded protection tube 80 includes a first tube portion 82 and a second tube portion 84 smaller than the first tube portion 82 in diameter, The connection point of the dummy cores 40 and the optical core wires 24 are inserted into the first tube portion 82 and the remaining portion of the dummy core 40 is inserted into the second tube portion 84 having a small diameter. The diameter of the first tube portion 82 can be provided so that a maximum of 12 heat shrink sleeves 50 can be received. That is, by using the expanded protection tube 80, it is possible to protect the plurality of dummy core 40 connection points (heat shrinkable sleeves) and the optical fibers in a single operation. When the expanded protective tube 80 is completely inserted, the end of the first tube portion 82 is fixed using a cable tie.

5A and 5B are diagrams for explaining a branching method capable of branching optical fiber lines from each of the loose tubes cut in half.

5A and 5B, after the rouge tube 22 to be used as the intermediate branch is cut in half, after each of the cut loose tubes 22 is removed from the exposed end leaving 60 mm and the outer skin is removed (Heat shrinkable sleeves) of the dummy cores 40 and the dummy cores 40 connected to the optical core wires 24 by using the expanded protective tube, Lt; / RTI > The reason why the dummy core 40 is connected to each of the loose tubes 22 is that the dummy core connection operation is inconvenient after the optical cable is installed in the enclosure 100,

As shown in FIG. 3G, a single-piece cable gasket 114 is cut by cutting a side surface of a conventional optical fiber cable 20 branched from a root tube for an intermediate branch with a knife (or scissors). The one-piece cable gasket 114 is mounted at a position spaced approximately 20 mm from the sheath cut surface.

3H, the one-piece cable gasket 114 is inserted into the branching optical fiber inlet 112 of the housing 100, and the optical fiber cable 20 is inserted into the optical fiber cable 20 through the jacket holder 113 and the cable fixing bracket 115, As shown in Fig. Then, the extend protection tube 80 is positioned to pass through the protective tube guide 150 installed in the middle of the bottom of the housing, and then fixed with a cable tie.

Referring to Figs. 4A to 4C, the newly installed optical cable 30 is removed about 1200 mm. The CSM (Central Strength Member) 38 is cut at a distance of 80 mm. The roots tube 32 to be used for exposing the optical fiber 34 is removed by leaving 80 mm. The unit protection tube 90 is inserted into the vented rouge tube 32. The unit protection tube 90 is pushed to the cable cut surface. In one example, the length of the unit protective tube 90 is 550 mm. Secure the unit protection tube (90) using insulating tape and apply vacuum grease to the cable cut surface area.

  After the end of the cone-shaped cable gasket 118 is cut with a knife (or scissors), the cut cone-shaped cable gasket is inserted into the optical cable inlet 116 for connection of the enclosure. The newly uncut optical cable is inserted into the housing 100 through a cone-shaped cable gasket, and the optical cable enclosure is fixed to the enclosure holder 113 and the sub band bracket. The center line 38 is fixed to the center line fixing module 160 as a center.

The unit protection tube fitted in the loose tube of the new optical fiber cable 30 passes through the protective tube guide in crossed or parallel fashion with the expand protection tube 80 and is fixed to the filter plate. The unit protection tube can be secured to the faceplate using a cable tie. The optical core wires drawn from the unit protective tube can be restored to the major plate 150 while maintaining the radius of curvature.

As described above, in the optical cable branching method in the intermediate branching non-branching optical fiber bundle, only the optical fiber core is branched directly in units of loose tubes at the optimum point (branching point) of the existing optical fiber cable 20 in use, The core 40 and the expanded protection tube 80 can be utilized to conveniently protect the core and the junctions.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

20: Optical fiber cable 30: New optical cable
80: Expand protective tube 100: Enclosure
900: Hypothesis module

Claims (5)

Claims [1] A method for optical fiber branching in an intermediate fiber optic connection enclosure comprising:
Breaking the intermediate shell of the existing optical cable and cutting only the loose tube to be used as the intermediate branch among the plurality of loose tubes into half;
Connecting the dummy cores to extend the lengths of the optical fibers branched from the loose tube after removing the envelope of the loose tube cut in half;
Protecting an attachment point of the dummy cores and the dummy cores connected to the optical fibers with an expanded protection tube; And
Attaching the optical fiber cable to the housing so that the loose tube cut in half and the dummy cores are located in the housing,
The expanded protection tube
Characterized in that the connection points of the dummy cores and the optical core wires are located in a first tube of the expanded protective tube and the dummy core is located in a second tube extending from the first tube and smaller in diameter than the first tube The optical fiber branching method in a non-optical fiber connection enclosure for an intermediate branch. The method according to claim 1,
In the step of mounting the existing optical cable to the housing
Wherein the extension protection tube is passed through a protective tube guide provided at the bottom of the housing and is then fixed to the filter board. 3. The method of claim 2,
Preparing a new cable, removing the loose tube of the new cable, and protecting the loose tube of the new cable using a unit protection tube;
And attaching the new cable to the housing. The method of claim 1, The method of claim 3,
In the step of mounting the new cable to the housing
Wherein the unit protection tube passes through the protective tube guide in an intersecting or parallel manner with the expanded protection tube and the X-shaped protrusion, and then is fixed to the swivel plate.
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